The present disclosure relates generally to a trip system for a circuit breaker, and particularly to an apparatus and method for adjusting a trip unit of the trip system.
Electrical circuit breakers may employ a variety of trip units for sensing an electrical current and for initiating a tripping action at the circuit breaker, including bimetallic, magnetic, and thermal/magnetic trip units. Magnetic trip units may include c-shaped magnets, oil-filled dashpots, coil-type solenoids, and the like. Circuit breaker manufacturing processes employing such trip units may include a calibration routine to properly coordinate the responsiveness of the trip unit to an electrical current and to properly adjust for dimensional variations and tolerances among and between the circuit breaker components. One such calibration routine involves the setting of different parameters, such as a magnetic air gap and a mechanical air gap for example. However, the adjustment of one parameter may effect the adjustment of another parameter, which may then need to be readjusted. Accordingly, there is a need in the art for a trip system for a circuit breaker that overcomes these drawbacks.
In one embodiment, a trip system for a circuit breaker having a calibration system is disclosed. The calibration system includes a retainer, a tripping member responsive to an electric current, an actuator retained by the retainer, a spring adjuster adjustably engaged with the actuator and the tripping member, and a bias spring disposed for biasing the actuator in a first direction. Movement of the spring adjuster absent movement of the actuator and the tripping member results in a change in the bias spring force and no change in the position of the tripping member, and movement of the tripping member absent movement of the spring adjuster results in a change in the position of the tripping member and no change in the bias spring force.
In another embodiment, a trip system for a circuit breaker having a calibration system is disclosed. The calibration system includes a bias spring for defining a trip force, a tripping member responsive to a magnetic flux across an air gap for overcoming the trip force and for generating a trip displacement, means for adjusting the trip force in the absence of adjustment to the air gap, and means for adjusting the air gap in the absence of adjustment to the trip force.
In a further embodiment, a method for calibrating a trip unit of a circuit breaker is disclosed. The position of a spring adjuster is fixed to prevent a change in trip force, the position of a tripping member is adjusted to change the dimension of a first air gap at the trip unit, the position of the tripping member is fixed to prevent any further change in the first air gap, the position of an actuator is fixed to prevent a change in a second air gap at the trip unit, and the position of the spring adjuster is adjusted to change the trip force.
Referring to the exemplary drawings wherein like elements are numbered alike in the accompanying Figures:
An embodiment of the invention provides a trip system for a circuit breaker. While the embodiment described herein depicts a magnetic trip unit as an exemplary trip system, it will be appreciated that the disclosed invention is also applicable to other trip systems, such as a bimetallic or a thermal/magnetic trip unit for example.
Trip system 200, best seen by now referring to
Trip unit 300 includes a trip coil 305 for accepting an electric current and for generating a magnetic flux in response thereto, a flux path 310 arranged proximate trip coil 305 for concentrating the magnetic flux and directing it to a stationary pole face 315, and a tripping member 320 having a first end 321 responsive to the magnetic flux of the electric current and a second end 322 having an actuator 325 for interacting with trip bar 225. In an embodiment, tripping member 320 is slidably arranged within the center of trip coil 305 and includes a movable pole face 330 at first end 321 that magnetically interacts with stationary pole face 315.
In an embodiment, flux path 310 may be fabricated from two flux paths; an upper flux path 311 and a lower flux path 312, having a flux bridge via a tab or dovetail connection 313. In this manner, the assembly of trip coil 305 and flux path 310 may be more easily assembled. Furthermore, upper flux path 311 may be fabricated with a drawn hole through which tripping member 320 axially translates, thereby improving the flux distribution between upper flux path 311 and tripping member 320, and reducing the reluctance across the air gap thereat.
Trip unit 300 also includes a cage 335 pivotally coupled to crossbar 210 at pivot 220, as discussed previously, which includes side legs 336 for housing bias spring 340, and a bottom section 337 for slidably engaging with tripping member 320. Accordingly, cage 335 and tripping member 320 are coupled together with a degree of freedom therebetween. Actuator 325 is threadably engaged with second end 322 of tripping member 320, thereby enabling adjustment therebetween, discussed further later. Corners 326 of actuator 325 slidably engage with side legs 336 of cage 335, thereby preventing rotation of actuator 325 as tripping member 320 is rotated, discussed further later, while providing a degree of freedom between actuator 325 and cage 335. In an embodiment, bias spring 340 is a compression spring, which is captivated between actuator 325 and bottom section 337 of cage 335, and which contributes to the trip force that needs to be overcome before circuit breaker 100 trips. Accordingly, bias spring 340 biases tripping member 320 and actuator 325 upward (a first direction), as depicted in FIG. 2.
Referring now to
Referring now to
Referring now back to
In view of the foregoing, the responsiveness of trip unit 300 to an electric current and associated magnetic flux may be adjusted by: adjusting both first and second air gaps 345, 350 in unison; adjusting second air gap 350 while maintaining first air gap 345 constant; adjusting second air gap 350 to be less than first air gap 345; and, fixing the second air gap 350 to be constant, by applying an adhesive to the threaded engagement of second end 322 and actuator 325, for example. By employing a common support frame 205 to tightly control the dimensional relationship of parts and assemblies involved in the tripping action of circuit breaker 100, first and second air gaps 345, 350 may be readily adjusted while substantially reducing the trip level variation.
Referring now to
For use herein, a combination tool having a central section for engaging slotted end 323 and a peripheral section for engaging tool receptors 416, whereby the central and peripheral sections are separately engagable and rotatable with the respective details 323, 416, is contemplated. Such a tool may be employed in an automated calibration routine.
By rotating spring adjuster 415 while holding actuator 410 and tripping member 320 fixed, spring adjuster 415 can move along common axis 420 in the absence of axial movement of tripping member 320, thereby resulting in a change in the bias force of bias spring 340 without producing a change in the dimension of first air gap 345. Similarly, by rotating tripping member 320 while holding spring adjuster 415 fixed, tripping member 320 can move along common axis 420 in the absence of axial movement of spring adjuster 415, thereby resulting in a change in the dimension of first air gap 345 without producing a change in the bias force of bias spring 340.
In view of the foregoing, trip unit 300 of circuit breaker 100 may be calibrated by: fixing the position of spring adjuster 415 to prevent a change in the bias force at bias spring 340 and therefore a change in trip force; adjusting (in an embodiment rotating) the position of tripping member 320 to change the dimension of first air gap 345 at trip unit 300; fixing the position of tripping member 320 to prevent any further change in the dimension of first air gap 345; fixing the position of actuator 410 to prevent a change in second air gap 350; adjusting (in an embodiment rotating) the position of spring adjuster 415 to change the bias force of bias spring 340 and therefore the trip force. By employing an actuator assembly 405 having separately adjustable tripping member 320 and spring adjuster 415, first air gap 345 and the bias force of bias spring 340 may be separately adjusted independent of the other, thereby providing a greater degree of control during a calibration routine of trip system 200.
As disclosed herein, some embodiments of the invention may include some of the following advantages: adjustability of first and second air gaps 345, 350 with substantial reduction in trip level variation; improved calibration control by having separately adjustable bias force at bias spring 340 and magnetic air gap at first air gap 345; reduced tolerance stack up between moving parts by having a common support frame 205 act as a common datum; ease of assembly through use of modular design with common support frame 205; and, independent control of different calibration parameters.
While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best or only mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims. Moreover, the use of the terms first, second, etc. do not denote any order or importance, but rather the terms first, second, etc. are used to distinguish one element from another. Furthermore, the use of the terms a, an, etc. do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced item.
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3908110 | Heft | Sep 1975 | A |
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Number | Date | Country |
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0913848 | May 1999 | EP |
11003647 | Jan 1999 | JP |
11102634 | Apr 1999 | JP |
11329200 | Nov 1999 | JP |
8803336 | May 1998 | WO |
Number | Date | Country | |
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20050062568 A1 | Mar 2005 | US |